% File src/library/datasets/man/crimtab.Rd
% Part of the R package, https://www.R-project.org
% Copyright 1995-2025 R Core Team
% Distributed under GPL 2 or later

\name{crimtab}
\alias{crimtab}
\docType{data}
\title{Student's 3000 Criminals Data}
\description{
  Data of 3000 male criminals over 20 years old undergoing their
  sentences in the chief prisons of England and Wales.
}
\usage{crimtab}
\format{
  A \code{\link{table}} object of  \code{\link{integer}} counts, of dimension
  \eqn{42 \times 22}{42 * 22} with a total count, \code{sum(crimtab)} of
  3000.

  The 42 \code{\link{rownames}} (\code{"9.4"}, \code{"9.5"}, \dots)
  correspond to midpoints of intervals of finger lengths
  whereas the 22 column names (\code{\link{colnames}})
  (\code{"142.24"}, \code{"144.78"}, \dots) correspond to (body) heights
  of 3000 criminals, see also below.
}
\details{
  Student is the pseudonym of \I{William Sealy Gosset}.
  In his 1908 paper he wrote (on page 13) at the beginning of section VI
  entitled \emph{Practical Test of the forgoing Equations}:

  \dQuote{Before I had succeeded in solving my problem analytically,
    I had endeavoured to do so empirically.  The material used was a
    correlation table containing the height and left middle finger
    measurements of 3000 criminals, from a paper by
    \bibcitet{|R:MacDonell:1902|p.\\\\\\sspace{}219)}.
    The
    measurements were written 
    out on 3000 pieces of cardboard, which were then very thoroughly
    shuffled and drawn at random.  As each card was drawn its numbers
    were written down in a book, which thus contains the measurements of
    3000 criminals in a random order.  Finally, each consecutive set of
    4 was taken as a sample---750 in all---and the mean, standard
    deviation, and correlation of each sample determined.  The
    difference between the mean of each sample and the mean of the
    population was then divided by the standard deviation of the sample,
    giving us the \emph{z} of Section III.}

  The table is in fact page 216 and not page 219 in
  \bibcitep{R:MacDonell:1902}.
  In the \I{MacDonell} table, the middle finger lengths were given in mm
  and the heights in feet/inches intervals, they are both converted into
  cm here.  The midpoints of intervals were used, e.g., where \I{MacDonell}
  has \eqn{4' 7''9/16 -- 8''9/16}, we have 142.24 which is 2.54*56 =
  2.54*(\eqn{4' 8''}).

  \I{MacDonell} credited the source of data (page 178) as follows:
  \emph{The data on which the memoir is based were obtained, through the
    kindness of Dr \I{Garson}, from the Central Metric Office, New Scotland Yard...}
  He pointed out on page 179 that : \emph{The forms were drawn at random
    from the mass on the office shelves; we are therefore dealing with a
    random sampling.}
}
\source{
  \url{https://pbil.univ-lyon1.fr/R/donnees/criminals1902.txt}
  thanks to Jean R. Lobry and \enc{Anne-Béatrice}{Anne-Beatrice} Dufour.
}
\references{
  \bibshow{*, R:Garson:1900, R:Student:1908}
}
\examples{
require(stats)
dim(crimtab)
utils::str(crimtab)
## for nicer printing:
local({cT <- crimtab
       colnames(cT) <- substring(colnames(cT), 2, 3)
       print(cT, zero.print = " ")
})

## Repeat Student's experiment:

# 1) Reconstitute 3000 raw data for heights in inches and rounded to
#    nearest integer as in Student's paper:

(heIn <- round(as.numeric(colnames(crimtab)) / 2.54))
d.hei <- data.frame(height = rep(heIn, colSums(crimtab)))

# 2) shuffle the data:

set.seed(1)
d.hei <- d.hei[sample(1:3000), , drop = FALSE]

# 3) Make 750 samples each of size 4:

d.hei$sample <- as.factor(rep(1:750, each = 4))

# 4) Compute the means and standard deviations (n) for the 750 samples:

h.mean <- with(d.hei, tapply(height, sample, FUN = mean))
h.sd   <- with(d.hei, tapply(height, sample, FUN = sd)) * sqrt(3/4)

# 5) Compute the difference between the mean of each sample and
#    the mean of the population and then divide by the
#    standard deviation of the sample:

zobs <- (h.mean - mean(d.hei[,"height"]))/h.sd

# 6) Replace infinite values by +/- 6 as in Student's paper:

zobs[infZ <- is.infinite(zobs)] # none of them 
zobs[infZ] <- 6 * sign(zobs[infZ])

# 7) Plot the distribution:

require(grDevices); require(graphics)
hist(x = zobs, probability = TRUE, xlab = "Student's z",
     col = grey(0.8), border = grey(0.5),
     main = "Distribution of Student's z score  for 'crimtab' data")
}
\keyword{datasets}
